JP2006278121A - Lighting control system and lighting control device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a lighting control system and lighting control device capable of easily and surely changing a changing speed of a lighting pattern. <P>SOLUTION: A general control unit 2 outputs a renewing signal including renewing number set by a setting operation part 14 to the lighting control unit 4. A plurality of fixed pattern data showing time-sequential changing state of lighting pattern of a neon-unit 24 are recorded to a memory 22M of the lighting control unit 24. A lighting control part 22 changes the renewal period between respective fixed pattern data by finding intermediate data at respective dividing points divided by the renewing number included in the renewal signal, by interpolating respective fixed pattern data; and by sequentially renewing the intermediate data corresponding to respective dividing points at every passage of periodical renewal period set in advance. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a lighting control system and a lighting control device that control lighting patterns of a plurality of lighting modules having light emitters such as neon lights and LEDs.

  For example, a neon lighting system such as a huge neon signboard provided on the roof of a building is configured by using a large number of neon lights, and the neon lights repeatedly turn on and off in a predetermined pattern. A certain lighting mode is realized. Such a neon lighting system includes a plurality of lighting modules that control lighting of the corresponding neon lamps, and the lighting effect of the neon lamps corresponding to the lighting modules is changed as needed to achieve the effect.

As this type of neon lighting system, a lighting control system described in, for example, Patent Document 1 has been proposed.
The lighting control system includes a plurality of lighting control units that respectively control turning on / off and brightness (lighting patterns) of the corresponding neon lights, and a general control unit that updates the lighting patterns of the neon lights by the respective lighting control units. Yes. Specifically, each lighting control unit has an individual address, and the overall control unit has address data indicating one of those addresses and pattern data indicating a time-series change mode of the lighting pattern. And transmission data comprising the synchronization code is output to each lighting control unit. Each lighting control unit stores the pattern data included in the transmission data in a memory or a spare memory when the address data included in the transmission data matches the address set in itself. Each lighting control unit updates the pattern data based on the synchronization code included in the transmission data, and switches from the current lighting mode to the next lighting mode. That is, each lighting control unit lights a neon lamp in a manner based on new pattern data each time a synchronization code is input.

Therefore, in such a lighting control system, the lighting pattern of the neon lamp by the plurality of lighting control units can be surely synchronized and updated, so that lighting control having a production effect can be performed with high accuracy.
Japanese Patent No. 2759120

  By the way, the change rate of the lighting pattern in such a neon lighting system is determined by the transmission cycle of transmission data from the overall control unit to each lighting control unit and the pattern data. That is, when the transmission cycle of the transmission data is short, or when the pattern data is set so that the lighting pattern changes frequently each time it is updated, the change rate of the lighting pattern increases. On the other hand, when the transmission cycle of the transmission data is long, or when the pattern data is set so that the lighting pattern does not change much even if it is updated, the change rate of the lighting pattern becomes slow. Therefore, conventionally, in order to change the change rate of the lighting pattern, it has been necessary to change the transmission cycle and pattern data of the transmission data.

  However, in order to change the transmission cycle of the transmission data, it is necessary to change the communication speed between the units or, in some cases, change the communication protocol. Also, in order to change the pattern data, it is necessary to change the design of each pattern data. Therefore, it is difficult to easily perform these change operations.

  The present invention has been made in view of such circumstances, and an object of the present invention is to provide a lighting control system and a lighting control device capable of easily and reliably changing the changing speed of the lighting pattern.

  In order to solve the above-described problems, in the invention described in claim 1, a recording means for recording a plurality of fixed pattern data indicating a time-series change mode of a lighting pattern of a light emitter, and an input update signal And a lighting control unit having a lighting control means for controlling the lighting pattern of the light emitter by sequentially updating the fixed pattern data based on the lighting control unit and connected to the lighting control unit via a network. A lighting control system comprising an overall control unit that sequentially outputs the update signals to the control unit, wherein the overall control unit receives update number data indicating the number of updates set to be changeable between the fixed pattern data. It includes a speed control means that is included in the update signal and output to the lighting control unit, and the lighting control means includes the Intermediate data at each point divided by the new number of times is obtained by interpolating between each fixed pattern data, and each time the preset periodic update time elapses, the intermediate data corresponding to each point is sequentially The gist is to change the update time between each fixed pattern data by updating.

  According to a second aspect of the present invention, in the lighting control system according to the first aspect, each of the fixed pattern data is constituted by a pair of pattern data each including start data and end data, and the lighting control means includes: Immediately after the update of the fixed pattern data, the light emitter is turned on with a lighting pattern based on the start data, and at the time of updating at the regular update time until the next fixed pattern data is updated, The gist of the invention is to turn on the light emitter with a lighting pattern based on intermediate data obtained from the data change amount between the start data and the end data.

  In the invention according to claim 3, a lighting control unit that controls a lighting pattern of the light emitter based on an input update signal, and a network connection with the lighting control unit, the lighting control unit is connected to each lighting control unit via the network. A lighting control system comprising an overall control unit that sequentially outputs update signals, wherein the overall control unit includes a recording unit that records a plurality of fixed pattern data indicating a time-series variation of the lighting pattern; While each fixed pattern data is sequentially output as the update signal for each calculation time obtained by multiplying the number of updates that can be changed between each fixed pattern data and a preset periodic update time, the number of updates The intermediate data at each point divided by the above is obtained by interpolating between each fixed pattern data. , Each time the periodic update time has elapsed, the gist further comprising an update control means for sequentially outputting the intermediate data to which the corresponding to each point on each of the periodic update time as the update signal.

  According to a fourth aspect of the present invention, in the lighting control system according to the third aspect, each of the fixed pattern data is constituted by a pair of pattern data each including start data and end data, and the update control means includes: When outputting the fixed pattern data as the update signal, start data is output, and when outputting the intermediate data as the update signal, interpolation is performed between the start data and the end data of the corresponding fixed pattern data. The gist is to output the intermediate data obtained by processing.

  In the invention according to claim 5, a lighting control unit for controlling a lighting pattern of a corresponding light emitter based on an input update signal, and a network connection with the lighting control unit, and each lighting control unit via the network And a general control unit that sequentially outputs the update signal, wherein the general control unit includes start data and end data, respectively, and indicates a time-series change mode of the lighting pattern. Recording means for recording a plurality of fixed pattern data, the fixed pattern data, and update number data indicating the number of updates set to be changeable between the fixed pattern data included in the update signal and output to the lighting control unit And a lighting control unit for receiving the start pattern of the input fixed pattern. Data and end data are divided by the number of times of update, and intermediate data at each of the divided points is obtained by interpolating between the start data and the end data, and a predetermined period is set. The gist of the invention is to include a lighting speed changing means for changing the update time between the fixed pattern data by sequentially updating the intermediate data corresponding to the points each time the update time elapses.

  The invention according to claim 6 is summarized in that, in the lighting control system according to any one of claims 1 to 5, the number of updates between the fixed pattern data can be individually set.

  In the invention according to claim 7, the lighting mode is based on a plurality of fixed pattern data indicating a time-series change mode of the lighting pattern of the light emitter and intermediate data obtained by performing interpolation processing between the fixed pattern data. A lighting control device comprising a lighting control means for controlling a lighting pattern of a light emitter by turning on the light emitter and sequentially updating the fixed pattern data and intermediate data at predetermined periodic update times. The fixed pattern data is composed of start data and end data, respectively, and the lighting control means turns on the light emitter in a lighting mode based on the start data immediately after the update, and updates the next fixed pattern data. At the time of the update every regular update time until the time, it is obtained from the data change amount between the start data and the end data And summarized in that in the lighting pattern based on the intermediate data to light the light emitting body.

  According to an eighth aspect of the present invention, the lighting control device according to the seventh aspect further includes an update number setting unit capable of changing an update number performed for each of the periodic update times between the fixed pattern data. To do.

The “action” of the present invention will be described below.
According to the first aspect of the present invention, if the value of the update count increases, the update time of the fixed pattern data becomes longer and the change rate of the lighting pattern becomes slower, and if the value of the update count decreases, the update time of the fixed pattern data becomes longer. It becomes shorter and the change rate of the lighting pattern becomes faster. That is, by changing the number of updates, the update time between the fixed pattern data can be changed, so that the change rate of the lighting pattern can be changed. In addition, during the regular update until the fixed pattern data is updated, the lighting mode is not significantly changed because the data is updated to intermediate data between the fixed pattern data. Further, since the fixed pattern data is recorded in the lighting control unit, there is no need to transmit the pattern data from the overall control unit to the lighting control unit, and the amount of transmission data can be reduced.

  According to the second aspect of the present invention, at the time of periodic update until the predetermined fixed pattern data (first fixed pattern data) is updated to the next fixed pattern data (second fixed pattern data), Since the data is updated to the intermediate data obtained from the data change amount between the start data and the end data of the first fixed pattern data, the lighting mode gradually changes based on the intermediate data. On the other hand, when the end data of the predetermined fixed pattern data and the start data of the next fixed pattern data are changed, the lighting pattern changes sharply when the intermediate data is updated to the fixed pattern data. In other words, the lighting pattern can be sharply changed by changing the end data of the predetermined fixed pattern data and the start data of the next fixed pattern data.

  According to the third aspect of the invention, the output cycle of the fixed pattern data is changed according to the value of the update count, and if the value of the update count is increased, the output cycle of the fixed pattern data is lengthened and the change rate of the lighting pattern is slow. Become. On the other hand, if the value of the update count is decreased, the output cycle of the fixed pattern data is shortened and the change rate of the lighting pattern is increased. Therefore, by changing the number of updates, the update time between the fixed pattern data can be changed, so that the change rate of the lighting pattern can be changed. In addition, since it is updated based on intermediate data composed of interpolation values between fixed pattern data during regular update, the lighting mode does not change significantly. In addition, since processing is performed only by the overall control unit, and the lighting control unit only needs to perform lighting control based on the input data, even when a plurality of lighting control units are connected to the overall control unit. The change rate of the lighting pattern of all the lighting control units can be changed only by the control of the overall control unit.

According to the fourth aspect of the present invention, the same effect as in the second aspect can be obtained.
According to the invention described in claim 5, if the value of the update count increases, the update time of the fixed pattern data becomes longer and the change rate of the lighting pattern becomes slower, and if the value of the update count decreases, the update time of the fixed pattern data Shorter and faster lighting pattern change speed. That is, by changing the number of updates, the update time between the fixed pattern data can be changed, so that the change rate of the lighting pattern can be changed. Further, at the time of periodic update until the fixed pattern data is updated, the lighting mode is not significantly changed because the data is updated to intermediate data between the fixed pattern data. Moreover, the lighting pattern can be changed sharply by changing the end data of the predetermined fixed pattern data and the start data of the next fixed pattern data.

According to the sixth aspect of the present invention, since the update time between the fixed pattern data can be individually changed, a partial speed change is possible.
According to the seventh aspect of the present invention, at the time of periodic update until the predetermined fixed pattern data (first fixed pattern data) is updated to the next fixed pattern data (second fixed pattern data), The first fixed pattern data is updated to intermediate data obtained from the data change amount between the start data and the end data. For this reason, until the fixed pattern is updated, the lighting mode gradually changes based on the intermediate data. On the other hand, if the end data value of the first fixed pattern data and the start data value of the second fixed pattern data are set to different values, the lighting pattern changes sharply when the fixed pattern data is updated. In other words, the lighting pattern can be sharply changed by changing the end data of the predetermined fixed pattern data and the start data of the next fixed pattern data.

  According to the invention described in claim 8, if the value of the update count increases, the update time of the fixed pattern data becomes longer and the change rate of the lighting pattern becomes slower, and if the value of the update count decreases, the update time of the fixed pattern data becomes longer. It becomes shorter and the change rate of the lighting pattern becomes faster. That is, by changing the number of updates by the update number setting means, it is possible to change the update time between the fixed pattern data, so that the change rate of the lighting pattern can be changed.

  As described above in detail, according to the present invention, it is possible to provide a lighting control system and a lighting control device capable of easily and reliably changing the changing speed of the lighting pattern.

<First Embodiment>
Hereinafter, a first embodiment of the present invention will be described in detail with reference to FIGS.
As shown in FIG. 1, the lighting control system 1 includes an overall control unit 2 and a plurality of lighting control units 4 that are network-connected to the overall control unit 2 via a bus 3. For this reason, communication is possible between the overall control unit 2 and each lighting control unit 4. In the present embodiment, it is assumed that 25 lighting control units 4 are connected to the overall control unit 2, and only the first to fourth lighting control units 4a to 4d are shown in FIG. And Incidentally, the number of lighting control units 4 that can be connected to the overall control unit 2 depends on the driver of the overall control unit 2 and is not limited to 25 lighting control units 4, for example, 100 lighting control units are connected. It is also possible to do.

  Each lighting control unit 4 is connected to an AC power source (100 V, 60 Hz commercial power source here), and the overall control unit 2 is connected to a DC power source obtained by converting the AC power source into a DC by an AC / DC converter 5. .

  The overall control unit 2 includes a communication interface 11 connected to the bus 3, an update control unit 12 as a speed control unit, a switching operation unit 13, and a setting operation unit 14 as an update count setting unit.

The communication interface 11 transmits various signals input from the update control unit 12 to each lighting control unit 4 via the bus 3.
The switching operation unit 13 includes a dip switch or the like and is connected to the update control unit 12. The switching operation unit 13 can perform a mode switching operation for switching the mode of the update control unit 12. Therefore, when the operation is performed by the switching operation unit 13, the operation signal is input to the update control unit 12.

  The setting operation unit 14 includes a dip switch or the like and is connected to the update control unit 12. The setting operation unit 14 can be operated to set the number of updates between fixed pattern data set in each lighting control unit 4.

  The update control unit 12 is a CPU unit including a CPU, a ROM, a RAM, and the like (not shown), and includes a nonvolatile memory 12M. In the present embodiment, a plurality of number data corresponding to positive integer values is recorded in the memory 12M. Then, the update control unit 12 sends an update signal including the number data, the number of updates set by the setting operation unit 14, and a division number based on the number of updates to a preset periodic update time (in this embodiment, 10). Output to the communication interface 11 every millisecond).

  Specifically, when outputting the number data, the update control unit 12 first outputs an update signal including number data corresponding to “0”, and thereafter, “1”, “2”, “3”,. Thus, the number data corresponding to the positive integer value added by 1 is output to update the number data. Note that the update control unit 12 outputs an update signal including the same number data for the set number of updates for each periodic update time, and then outputs an update signal including the number data obtained by adding “1”. Note that the update control unit 12 is not necessarily limited to updating the number data incremented by one when the number data is updated. For example, the number data corresponding to “1” to the number data corresponding to “5”. It is also possible to update to completely different number data such as updating to

  Further, when outputting the update signal, the update control unit 12 outputs the update signal including the number of updates and the division number in addition to the number data. The number of updates is set by the setting operation unit 14. For example, when the number of updates is set to “10”, the update control unit 12 outputs an update signal indicating that the number of updates is “10”. More specifically, the update control unit 12 outputs a division number “0” included in the update signal when starting to output new number data. Then, the update control unit 12 sets the division number to 1 every time the regular update time (“Δt” shown in FIG. 4) elapses, such as division number “1” → “2” → “3”. Until the division number “9” is output, the update signal including the same number data and the number of updates is output.

  Further, when a signal indicating that the mode switching operation has been performed (mode switching signal) is input from the switching operation unit 13, the update control unit 12 switches to the normal mode or the data rewrite mode according to the mode switching signal. Change. Incidentally, in the normal mode, the update control unit 12 outputs the number data. On the other hand, in the data rewrite mode, the update control unit 12 receives data indicating the data rewrite mode, pattern data input from the external input device 6, and address data for designating each lighting control unit 4. The rewrite signal including the signal is output to the communication interface 11. The address data is set in correspondence with the setting state of the address setting unit 23 of each lighting control unit 4 to be described later.

  On the other hand, each lighting control unit 4 includes a communication interface 21, a lighting control unit 22, and an address setting unit 23, respectively. In FIG. 1, only the configuration of the first lighting control unit 4a is shown in detail, but the second to fourth lighting control units 4b to 4c also have the same configuration as the first lighting control unit 4a.

The communication interface 21 receives various signals output from the overall control unit 2 via the bus 3 and outputs them to the lighting control unit 22.
The address setting unit 23 includes an operation unit such as a dip switch having eight switch units, for example, and is set so that the setting states of the lighting control units 4 are not the same. A setting signal indicating the setting state of the address setting unit 23 is input to the lighting control unit 22.

  A neon unit 24 as a light emitter is connected to the lighting control unit 22 of each lighting control unit 4. Each of the neon units 24 includes a plurality of neon tubes and a neon transformer for causing the neon tubes to emit light (not shown). In the present embodiment, the neon unit 24 includes a plurality of neon tubes of three colors, red, blue, and green. Such a neon unit 24 causes the corresponding neon tube to emit light based on the control signal output from the lighting control unit 22.

  The lighting control unit 22 is a CPU unit including a CPU, ROM, RAM, and the like (not shown), and performs lighting control and data rewrite control of the neon unit 24 based on various signals output from the overall control unit 2.

  The lighting control unit 22 includes a nonvolatile memory 22M as recording means. In the present embodiment, in the memory 22M, the plurality of number data and a plurality of fixed pattern data indicating a time-series change mode of the lighting pattern of the neon unit 24 are recorded in association with each other.

  Specifically, as shown in FIG. 2, for example, number data corresponding to “0” and fixed pattern data indicated by “A-0” are recorded in the memory 22M of the first lighting control unit 4a in association with each other. The number data corresponding to “1” and the fixed pattern data indicated by “A-1” are recorded in association with each other. In this way, each number data and fixed pattern, such as fixed pattern data “A-2” for number data “2”, fixed pattern data “A-3” for number data “3”, etc. Data is associated with the data and recorded in the memory 22M.

  Similarly, in the memory 22M of the second lighting control unit 4b, the fixed pattern data “B-0” for the number data “0”, the fixed pattern data “B-1” for the number data “1”, the number Each number data is associated with fixed pattern data, such as fixed pattern data “B-2” for data “2”, fixed pattern data “B-3” for number data “3”, and so on. Has been recorded.

  That is, even with the same number data, the fixed pattern data recorded in the memory 22M of the first lighting control unit 4a and the fixed pattern data recorded in the memory 22M of the second lighting control unit 4b are different from each other. Can be set. However, these fixed pattern data are not necessarily different, and the whole or a part (for example, “A-2” and “B-2”) may be the same.

  In addition, as shown in FIG. 3A, in this embodiment, start data and end data are set in each fixed pattern data (here, “A-0” to “A-13” are shown). ing. For this reason, when the update signal is input from the overall control unit 2, the lighting control unit 22 performs lighting control of the corresponding neon unit 24 based on the start data and the end data. Therefore, the lighting control of the neon unit 24 performed by the lighting control unit 22 will be described in detail below. FIG. 3A shows the relationship among the number data indicating the lighting pattern of the red neon tube, the fixed pattern data, the start data, and the end data in the lighting control unit 22 of the first lighting control unit 4a. FIG. 3B shows a graph when the start data and end data of each fixed pattern data are linearly interpolated.

(Lighting control of the neon unit 24 based on the update signal)
When the update signal from the overall control unit 2 is input via the bus 3 and the communication interface 21, the lighting control unit 22 first reads out the fixed pattern data corresponding to the number data included in the update signal from the memory 22M. .

  Then, the lighting control unit 22 determines the intermediate at each division point divided by the number of updates from the data change amount between the start data and the end data of the read fixed pattern data and the number of updates included in the update signal. Calculate the data. Specifically, as shown in FIG. 4, first, the lighting control unit 22 performs a linear interpolation process between the start data and the end data of the fixed pattern data corresponding to the number data included in the update signal, and between the two data. Intermediate data at is calculated. For example, when the number of updates is set to “10”, the lighting control unit 22 divides the data change amount between the two data calculated by the linear interpolation process into 10 parts, and “ A division point of “0” to “9” is given. Here, the lighting control unit 22 sets the start point (start data of fixed pattern data corresponding to the number data included in the update signal) as a division point “0”, and sets the end point (end data of the fixed pattern data) as the next point. It is set as a division point “0” in the number data. Therefore, pattern data (intermediate data) corresponding to each division point is obtained. FIG. 4 is a graph showing enlarged intermediate data while the number data changes from “0” to “1”.

  Since an update signal including a division point added by 1 is input every time the regular update time Δt elapses, the lighting control unit 22 is based on intermediate data corresponding to the division point among the calculated intermediate data. The lighting pattern of the neon unit 24 will be updated. Therefore, as shown in FIG. 4, the update time between each number data (update time between each fixed pattern data) T is a time obtained by multiplying the regular update time Δt by the number of updates (here, “(10 × 10) mm”. Second ", ie" 100 milliseconds ").

  Therefore, in the lighting control system 1 configured as described above, each lighting control unit 4 receives the update signal output from the overall control unit 2 every 10 milliseconds, so that each neon unit 24 is turned on at the same timing. The pattern will be updated. In addition, since the number data is absolute value data, even if some of the lighting control units 4 cannot receive the update signal normally, the lighting control unit 4 is not updated at the next data update. If the update signal is normally received, all the lighting control units 4 update the pattern data based on the same number data. For this reason, the lighting pattern update timing does not deviate between the lighting control unit 4 that has successfully received the update signal and the lighting control unit 4 that has not normally received the update signal.

(Control flow between the overall control unit 2 and each lighting control unit 4)
Therefore, in the lighting control system 1 configured in this way, as shown by step S1 in FIG. 5, first, the overall control unit 2 updates each lighting control unit 4 including number data, the number of updates, and the division points. A signal is output.

  As shown in step S2, when the update signal is input, the lighting control unit 4 calculates intermediate data of each division point based on the fixed pattern data corresponding to the update number included in the update signal and the update count. To do.

And as shown by step S3, the lighting control unit 4 performs lighting control of the neon unit 24 based on the intermediate data corresponding to the division points included in the update signal.
Further, as shown in step S4, the overall control unit 2 outputs a new update signal to the lighting control unit 4 when the regular update time Δt has elapsed since the last (step S1) update signal was output.

  The lighting control unit 4 performs the process of step S3 when the number data included in the input update signal is the same as the previous time. On the other hand, when the number data included in the input update signal is different from the previous time, the lighting control unit 4 re-executes the processes of steps S2 and S3 based on the fixed pattern data corresponding to the number data. Do.

(Operation of start data and end data)
By the way, start data and end data are set for each fixed pattern data. For example, as shown in FIG. 3A, the end data value of the fixed pattern data “A-0” corresponding to the number data “0” is set to “30 (%)”, and the subsequent number data “1”. The value of the start data of the fixed pattern data “A-1” corresponding to “30-1%” is also set to “30 (%)”. That is, the end data value of the fixed pattern data “A-0” and the start data value of the next fixed pattern data “A-1” are set to be the same. For this reason, as shown in FIG. 3B, the value of the pattern data at the division point “0” of the number data “1” is necessarily “30 (%)”.

  On the other hand, as shown in FIG. 3A, the end data value of the fixed pattern data “A-7” corresponding to the number data “7” is set to “100 (%)”, and the subsequent number data The value of the start data of the fixed pattern data “A-8” corresponding to “8” is set to “0 (%)”. Therefore, as shown in FIGS. 3B and 6, the pattern data value at the division point “0” of the number data “8” is confused with “100 (%)” and “0 (%)”. It will be in the state. Therefore, the lighting control unit 22 updates the lighting pattern of the neon unit 24 based on the start data at the division point “0”. Therefore, at the division point “0” of the number data “8”, the lighting pattern of the neon unit 24 is updated based on the start data of the fixed pattern data “A-8”. Accordingly, the division point “0” of the number data “8” is reached even though the red neon tube of the neon unit 24 is lit at the duty ratio of 100% until the division point “9” of the number data “7”. At this time, the red neon tube is extinguished at once. Further, since the start data and end data values of the fixed pattern data “A-8” corresponding to the number data “8” are both “0 (%)”, each division point “0” of the number data “8” is displayed. The values of the intermediate data from “9” to “9” are all “0 (%)”. Then, the value of the pattern data becomes “100 (%)” again at the time of the division point “0” of the number data “9”.

  In this way, when the end data value of fixed pattern data corresponding to a certain number data is different from the start data value of fixed pattern data corresponding to the next number data, the number data is updated. In addition, the pattern data changes abruptly.

  On the other hand, when start data and end data are not set in each fixed pattern data, the number data and the fixed pattern data have a relationship as shown in FIGS. 7A and 7B, for example. That is, as shown in FIG. 7B, each intermediate data becomes a value that gradually decreases while the number data is updated from “7” to “8”, and when the number data is updated to “8”. The pattern data becomes “0 (%)”. Then, the intermediate data is gradually increased while the number data is updated from “8” to “9”. When the number data is updated to “9”, the pattern data is “100 (%)”. It becomes. That is, the pattern data does not change sharply in this case as compared with the transition of the pattern data (see FIG. 3B) when the start data and the end data are set in the fixed pattern data. Therefore, as the number of updates increases, the pattern data tends to gradually change over time. In other words, if the start data and end data cannot be set in the fixed pattern data, the pattern data cannot be changed sharply in a short time, and the start data and end data can be set in the fixed pattern data. Therefore, the pattern data can be changed rapidly in a short time.

(Data rewrite control)
When the rewrite signal output from the overall control unit 2 is input to the lighting control unit 22, the address data included in the rewrite signal and the address data indicated by the setting signal input from the address setting unit 23. Whether or not matches is determined. As a result, when it is determined that the address data match each other, the lighting control unit 22 records the pattern data included in the rewrite signal in the memory 22M. At this time, the lighting control unit 22 overwrites and updates the existing pattern data recorded in the memory 22M with new pattern data. On the other hand, when it is determined that the address data do not match, the lighting control unit 22 ignores the rewrite signal. Therefore, by operating the switching operation unit 13 of the overall control unit 2, the update control unit 12 is switched to the data rewriting mode, and new pattern data is input from the external input device 6 to the update control unit 12. The new pattern data can be recorded in the memory 22M of the lighting control unit 22 of the control unit 4.

(Relationship between update count and lighting pattern data over time)
Next, the relationship between the number of updates set by the setting operation unit 14 of the overall control unit 2 and the temporal transition of the lighting pattern will be described.

  For example, when the number of updates is set to “10” by the setting operation unit 14, the number data is updated every time the update time T elapses as shown in FIG. That is, in this case, the fixed pattern data is updated every time the update time T (= “100 milliseconds”) elapses. For this reason, when one lighting pattern is composed of number data “0” to “14”, the total time of the lighting pattern is (14 × T) seconds, that is, 1.4 seconds.

  On the other hand, for example, when the number of updates is set to “20” by the setting operation unit 14, as shown in FIG. 8B, the number data is updated every time the update time 2T (2 × T) elapses. The Rukoto. That is, in this case, the fixed pattern data is updated every time when the time twice as long as the update count is set to “10” (“200 milliseconds”) elapses. Therefore, when the number data is “0” to “14” to form one lighting pattern, the total time of the lighting pattern is (14 × 2 × T) seconds, that is, 2.8 seconds. Therefore, the total time of the lighting pattern is twice that when the number of updates is set to “10”. Therefore, the change rate of the lighting pattern can be changed by the number of updates.

Therefore, according to the present embodiment, the following effects can be obtained.
(1) If the value of the update count increases, the update time T of the fixed pattern data becomes longer and the change rate of the lighting pattern becomes slower. If the value of the update count decreases, the update time T of the fixed pattern data becomes shorter and the lighting pattern becomes shorter. The speed of change becomes faster. That is, since the update time between the fixed pattern data can be changed by changing the number of updates by the setting operation unit 14 of the overall control unit 2, the change rate of the lighting pattern of the neon unit 24 can be changed. Become. In addition, at the time of periodic update until the fixed pattern data is updated (at the time of updating every regular update time Δt), since the intermediate data between the fixed pattern data is updated, the lighting mode does not change significantly. .

  (2) Since the fixed pattern data is recorded in the memory 22M provided in the lighting control unit 22 of the lighting control unit 4, it is necessary to transmit fixed pattern data and intermediate data from the overall control unit 2 to the lighting control unit 4. The amount of transmission data is small.

  (3) Predetermined fixed pattern data (first fixed pattern data: for example, fixed pattern data corresponding to number data “0”) to next fixed pattern data (second fixed pattern data: for example, number data “1”) At the time of the periodic update until it is updated to (fixed pattern data), it is updated to intermediate data obtained from the number of updates and the data change amount between the start data and end data of the first fixed pattern data The lighting mode gradually changes based on the intermediate data. On the other hand, when the end data of the first fixed pattern data and the start data of the second fixed pattern data are different, the second fixed pattern data is updated when the intermediate data of the first fixed pattern data is updated to the second fixed pattern data. Lighting control is performed based on the data start data. For this reason, the lighting pattern of the corresponding neon unit 24 changes abruptly from the intermediate data until just before that to the start data. Therefore, the lighting pattern can be changed sharply by changing the end data of the predetermined fixed pattern data and the start data of the next fixed pattern data.

The first embodiment may be modified as follows.
In the first embodiment, the update control unit 12 of the overall control unit 2 controls each lighting control for the update signal including the number data, the number of updates, and the division point every regular update time Δt (10 milliseconds in the embodiment). It outputs to the unit 4. However, the update control unit 12 is a time obtained by multiplying the update signal including the number data and the update count by the periodic update time Δt (here, “(10 × 10) milliseconds”, that is, “100 milliseconds”). ) May be output to each lighting control unit 4 every time. And the lighting control part 22 of each lighting control unit 4 will read the fixed pattern data corresponding to the number data contained in this update signal from the memory 22M, if an update signal is input. At the same time, the lighting control unit 22 calculates intermediate data at each division point divided by the number of updates from the data change amount between the start data and end data of the read fixed pattern data and the number of updates. . Then, each time the regular update time Δt elapses, the lighting control unit 22 updates the corresponding intermediate data in order from the side closer to the start data (in the order of “0” → “9” of the division points). It may be. In this way, the communication frequency between the overall control unit 2 and each lighting control unit 4 can be reduced.

  In the first embodiment, the setting operation unit 14 can collectively change the number of updates between all the number data. However, the setting operation unit 14 may be capable of individually setting the number of updates between specific number data. In this way, since the update time between the fixed pattern data can be partially changed, the change rate of the lighting pattern of the neon unit 24 can be partially changed, and the fixed pattern data can be changed. The neon unit 24 can be lit with a lighting pattern with a completely different impression.

<Second Embodiment>
Next, a second embodiment embodying the present invention will be described with reference to FIGS. In the following embodiments, points different from the first embodiment will be mainly described, and common points will be simply denoted by the same member numbers, and description thereof will be omitted.

  As shown in FIG. 9, the configuration of the lighting control system 1 of the present embodiment is the same as that of the first embodiment, and the following points are different from the first embodiment. In the present embodiment, a plurality of lighting control units 4 are connected to the overall control unit 2 as in the first embodiment, but in FIG. 9, the plurality of lighting control units 4 are illustrated. The figure which abbreviate | omits and connected only to the overall control unit 2 is shown.

Contents recorded in the memory 12M of the update control unit 12
Processing performed by the update control unit 12 of the overall control unit 2
-Update signal content.

Processing performed by the lighting control unit 22 of the lighting control unit 4
Contents recorded in the memory 22M of the lighting control unit 22
Therefore, in the present embodiment, differences from the first embodiment will be described in detail.

(Memory 12M of update control unit 12)
In the memory 12M of the update control unit 12, the fixed pattern data indicating the time-series variation of the lighting pattern of each neon unit 24 is recorded. In the memory 12M, as shown in FIG. 3A, a plurality of fixed pattern data including the start data and the end data are recorded. The number data does not necessarily have to be recorded in the memory 12M, and it is sufficient that the update control unit 12 can recognize each fixed pattern data in time series.

(Processing of the update control unit 12)
The update control unit 12 serving as an update control unit performs intermediate data calculation processing performed by the lighting control unit 22 in the first embodiment. That is, the update control unit 12 is divided by the number of updates from the amount of change between the start data and the end data of the fixed pattern data recorded in the memory 12M and the number of updates set by the setting operation unit 14. The intermediate data at each division point is calculated. For example, when the number of updates is set to “10”, as described above, the linear interpolation process between the start data and the end data is performed, and the intermediate points at the division points “1” to “9” are performed. Calculate the data.

  Then, the update control unit 12 outputs one of the start data and intermediate data of each fixed pattern data as an update signal to the lighting control unit 4 in chronological order every time the regular update time Δt elapses. Specifically, the update control unit 12 performs lighting control using the start data of fixed pattern data (fixed pattern data corresponding to the number data “0” in the first embodiment) set in the earliest order as an update signal. Output to unit 4. Thereafter, every time the regular update time Δt elapses, the update control unit 12 performs division point “1”, division point “2”,... In the order between the start data and the end data of the fixed pattern data. Corresponding intermediate data is output to the lighting control unit 4 as an update signal. Then, the update control unit 12 outputs the intermediate data corresponding to the division point “9” to the lighting control unit 4, and then the fixed pattern data (the first pattern) set in the next order when the regular update time Δt has elapsed. The start data of the fixed pattern data corresponding to the number data “1” in one embodiment is output to the lighting control unit 4 as an update signal. That is, the overall control unit 2 outputs the start data of the fixed pattern data as an update signal to the lighting control unit 4 at every calculation time obtained by multiplying the regular update time Δt and the update count, while at the same time every regular update time Δt. The intermediate data is output to the lighting control unit 4 as an update signal. Therefore, the calculation time corresponds to the update time T of the fixed pattern data in the first embodiment, and when the regular update time Δt is set to “10 milliseconds” and the update count is set to “10”, “100 Milliseconds ".

(Processing of the lighting control unit 22)
On the other hand, when the update signal from the overall control unit 2 is input via the communication interface 21, the lighting control unit 22 of the lighting control unit 4 is based on the start data or intermediate data of the fixed pattern data included in the update signal. Thus, the lighting control of the corresponding neon unit 24 is performed. That is, in the present embodiment, the lighting control unit 4 only performs lighting control of the neon unit 24 based on the update signal. For this reason, no fixed pattern data is recorded in the memory 22M of the lighting control unit 22.

  In addition, when outputting the update signal, the update control unit 12 outputs pattern data (fixed pattern data, intermediate data) corresponding to each lighting control unit 4 individually as an update signal. Specifically, the update control unit 12 outputs data obtained by adding the address data of each lighting control unit 4 set by the address setting unit 23 to the pattern data to the bus 3 as an update signal. Therefore, the lighting control unit 22 of each lighting control unit 4 uses the update signal only when it is determined that the update signal corresponds to the address data set in itself based on the address data included in the update signal. The lighting control of the neon unit 24 is performed based on the included pattern data.

(Control flow between the overall control unit 2 and each lighting control unit 4)
Therefore, in the lighting control system 1 configured in this way, as shown in step S11 in FIG. 10, first, the update control unit 12 of the overall control unit 2 performs each division based on each fixed pattern data and the number of updates. Intermediate data at points is calculated.

Then, as shown in step S <b> 12, the fixed pattern data or the calculated intermediate data is output as an update signal from the overall control unit 2 to each lighting control unit 4.
As shown in step S13, when the update signal is input, the lighting control unit 4 performs the lighting control of the corresponding neon unit 24 based on the fixed pattern data or the intermediate data included in the update signal.

  Then, as shown in step S <b> 14, the overall control unit 2 outputs a new update signal to the lighting control unit 4 when the regular update time Δt has elapsed since the last (step S <b> 11) update signal was output.

  When a new update signal is input, the lighting control unit 4 performs lighting control of the corresponding neon unit 24 based on the fixed pattern data or the intermediate data included in the update signal, similarly to step S13.

That is, the lighting control of the neon unit 24 is performed by repeatedly performing the processing of steps S11 to S13 by the overall control unit 2 and each lighting control unit 4.
Therefore, according to this embodiment, in addition to the same effects as (1) and (3) in the first embodiment, the following effects can be obtained.

  (4) Since the pattern data calculation process is performed only by the overall control unit 2 and the output timing of the pattern data calculated by the calculation process is controlled, the lighting control unit 22 of the lighting control unit 4 is input. It is only necessary to simply perform lighting control based on the data. Therefore, even when a plurality of lighting control units 4 are connected to the overall control unit 2, the change rate of the lighting patterns of all the lighting control units can be changed only by the control of the overall control unit 2. Therefore, it is not necessary to use a high-performance CPU unit as the lighting control unit 22 of each lighting control unit 4, and the lighting control system 1 as a whole is inexpensive.

  (5) Fixed pattern data corresponding to each lighting control unit 4 is recorded in the memory 12M of the update control unit 12 in the overall control unit 2, and fixed pattern data is stored in the memory 22M of the lighting control unit 22 in each lighting control unit 4. There is no need to keep track of. For this reason, a small-capacity memory can be used as the memory 22M of each lighting control unit 22. In addition, the update control unit 12 does not need to transmit a rewrite signal including new fixed pattern data input from the external input device 6 to each lighting control unit 4 at the time of data rewrite control. Therefore, the data rewrite control can be easily performed. In addition, it can be performed quickly.

The second embodiment may be modified as follows.
In the second embodiment, the setting operation unit 14 can collectively change the number of updates between all the fixed pattern data. However, the setting operation unit 14 may be able to individually set the number of updates between specific fixed pattern data. In this way, since the update time between the fixed pattern data can be partially changed, the change rate of the lighting pattern of the neon unit 24 can be partially changed, and the fixed pattern data can be changed. The neon unit 24 can be lit with a lighting pattern with a completely different impression.

<Third Embodiment>
Next, a third embodiment of the present invention will be described with reference to FIGS.
As shown in FIG. 11, also in this embodiment, the structure of the lighting control system 1 has comprised the structure equivalent to each embodiment, and the points which are different from this each embodiment are shown below.

Processing performed by the update control unit 12 of the overall control unit 2
-Update signal content.
Processing performed by the lighting control unit 22 of the lighting control unit 4

Therefore, in the present embodiment, differences from the respective embodiments will be described in detail.
(Processing of the update control unit 12)
In the present embodiment, the fixed pattern data is recorded in the memory 12M of the update control unit 12 as in the second embodiment. Then, the update control unit 12 as speed control means outputs an update signal including fixed pattern data and update number data indicating the number of updates set by the setting operation unit 14 to the lighting control unit 4. Specifically, the update control unit 12 first sets fixed pattern data set in the earliest order among the fixed pattern data recorded in the memory 12M in time series (number data “0 in the first embodiment”). The update signal including the start data and end data of the fixed pattern data) and the update count data is output to the lighting control unit 4. Thereafter, the update control unit 12, when a time (update signal output time Tx shown in FIG. 12) obtained by multiplying the set number of updates by the periodic update time Δt has elapsed, The start data and end data of the fixed pattern data corresponding to the number data “1” in the first embodiment are output to the lighting control unit 4 as update signals. That is, the update control unit 12 outputs new fixed pattern data to the lighting control unit 4 every time the update signal output time Tx elapses. The update signal output time Tx in the present embodiment corresponds to the update time T of the fixed pattern data in the first and second embodiments, the regular update time Δt is “10 milliseconds”, and the number of updates is “10”. Is set to “100 milliseconds”.

(Processing of the lighting control unit 22)
On the other hand, in the present embodiment as well, as in the second embodiment, the fixed pattern data is not recorded in the memory 22M of the lighting control unit 22, and the lighting control unit 22 serving as the lighting speed changing means receives the update signal. The lighting control of the corresponding neon unit 24 is performed based on the included fixed pattern data. Specifically, when the update signal from the overall control unit 2 is input via the communication interface 21, the lighting control unit 22 changes the data between the start data and the end data of the fixed pattern data included in the update signal. From the amount and the number of updates, intermediate data at each division point divided by the number of updates is calculated. Specifically, as in the first embodiment, as shown in FIG. 4, first, the lighting control unit 22 performs a linear interpolation process between the start data and the end data, and obtains intermediate data between the two data. calculate. That is, for example, when the number of updates is set to “10”, the lighting control unit 22 divides the data change amount between the two data calculated by the linear interpolation process into 10 parts, and “ A division point of “0” to “9” is given.

  Then, the lighting control unit 22 performs lighting control of the corresponding neon unit 24 based on the pattern data (starting data of fixed pattern data) at the division point “0”. Thereafter, each time the regular update time Δt elapses, the lighting control unit 22 is based on the corresponding intermediate data in the order of division points “1” → “2” → “3” →. Then, the lighting control of the neon unit 24 is performed.

  In the present embodiment, as in the second embodiment, when the update control unit 12 outputs the update signal, the update signal includes fixed pattern data individually corresponding to each lighting control unit 4. It is designed to output. Specifically, the update control unit 12 outputs data obtained by adding the address data of each lighting control unit 4 set by the address setting unit 23 to the fixed pattern data to the bus 3 as an update signal. Therefore, the lighting control unit 22 of each lighting control unit 4 uses the update signal only when it is determined that the update signal corresponds to the address data set in itself based on the address data included in the update signal. The lighting control of the neon unit 24 is performed based on the included fixed pattern data.

(Control flow between the overall control unit 2 and each lighting control unit 4)
Therefore, in the lighting control system 1 configured as described above, as shown in step S21 in FIG. 12, first, the update signal including the fixed pattern data and the number of updates is controlled by the update control unit 12 of the overall control unit 2. Output to unit 4.

  As shown in step S22, when the lighting control unit 4 receives the update signal, the lighting control unit 22 causes the lighting control unit 22 to obtain intermediate data of each division point based on the fixed pattern data and the number of updates included in the update signal. calculate.

  Then, as shown in step S23, the lighting control unit 4 updates the data every time the regular update time Δt elapses, and performs the lighting control of the neon unit 24 based on the intermediate data of each division point.

  As shown in step S24, when the update signal output time Tx obtained by multiplying the periodic update time Δt by the update count has elapsed, the overall control unit 2 sends an update signal including new fixed pattern data and the update count to the lighting control unit 4. Output.

Then, the lighting control unit 4 repeats the processes of steps S22 and S23.
That is, the lighting control of the neon unit 24 is performed by repeatedly performing the processes of steps S21 to S23 by the overall control unit 2 and each lighting control unit 4.

Therefore, according to the present embodiment, in addition to the effects (1), (3), and (5) in the first embodiment, the following effects can be obtained.
(6) In the first embodiment, the lighting control unit 22 of the lighting control unit 4 reads the fixed pattern data corresponding to the input number data from the memory 22M, the start data of the read fixed pattern data, and It is necessary to perform processing for calculating intermediate data based on the end data. On the other hand, the update control unit 12 of the overall control unit 2 only performs a process of outputting an update signal including number data, the number of updates, and a division point to the lighting control unit 4. For this reason, in 1st Embodiment, it can be said that the process burden of the lighting control part 22 is large compared with the update control part 12. FIG.

  In the second embodiment, the fixed pattern data of all the lighting control units 4 is recorded in the memory 12M of the update control unit 12, and the update control unit 12 calculates intermediate data based on the fixed pattern data. The fixed pattern data and intermediate data are output. On the other hand, the lighting control unit 22 of each lighting control unit 4 only performs lighting control of the neon unit 24 based on fixed pattern data or intermediate data included in the input update signal. For this reason, in 2nd Embodiment, it can be said that the process burden of the update control part 12 is large compared with the lighting control part 22. FIG.

  On the other hand, in the present embodiment, the fixed pattern data is recorded in the memory 12M of the update control unit 12 of the overall control unit 2, and the output control of the fixed pattern data is performed by the update control unit 12. On the other hand, the calculation process of the intermediate data based on the start data and the end data of the fixed pattern data is performed by the lighting control unit 22 of each lighting control unit 4. Therefore, it can be said that the processes of the update control unit 12 and the lighting control unit 22 are distributed in a balanced manner as compared with the above embodiments. For this reason, it is possible to prevent the processing load necessary for performing the lighting control of the neon unit 24 from being biased toward the update control unit 12 or the lighting control unit 22.

The third embodiment may be modified as follows.
The update control unit 12 updates the start data and end data of the fixed pattern data set in the next order when a time (update signal output time Tx) obtained by multiplying the number of updates by the regular update time Δt has elapsed. Is output to the lighting control unit 4. However, the update control unit 12 uses the start data and the end data of the fixed pattern data set in the next order as update signals for each preset output time (<update signal output time Tx). May be output to. However, in this case, it is necessary for the lighting control unit 22 to once record start data and end data of newly input fixed pattern data in a buffer or the like.

  The update control unit 12 outputs an update trigger signal to the lighting control unit 4 at each regular update time Δt, and the lighting control unit 22 updates data when the update trigger signal is input. May be. That is, the lighting control unit 22 does not update the data every periodic update time Δt by its own determination, but updates the data based on the update trigger signal input from the update control unit 12. Good. If it does in this way, it will become possible to prevent certainly generating a gap in the data update timing of each lighting control unit 4.

  In the third embodiment, the setting operation unit 14 can collectively change the number of updates between all the fixed pattern data. However, the setting operation unit 14 may be able to individually set the number of updates between specific fixed pattern data. In this way, since the update time between the fixed pattern data can be partially changed, the change rate of the lighting pattern of the neon unit 24 can be partially changed, and the fixed pattern data can be changed. The neon unit 24 can be lit with a lighting pattern with a completely different impression.

<Fourth embodiment>
Next, a fourth embodiment embodying the present invention will be described with reference to FIGS.
The present embodiment differs from the first to third embodiments in that each of the embodiments is a lighting control system 1 including a general control unit 2 and a plurality of lighting control units 4, whereas in the present embodiment, a single unit is used. It is about the point which becomes the lighting control apparatus which consists of this lighting control unit 4.

Specifically, the lighting control unit (lighting control device) 4 includes a lighting control unit 22 as a lighting control unit, a switching operation unit 25, and a setting operation unit 26 as an update count setting unit.
A neon unit 24 as a light emitter is connected to the lighting control unit 22. The neon unit 24 includes a plurality of neon tubes and a neon transformer for causing the neon tubes to emit light (not shown). In the present embodiment, the neon unit 24 includes a plurality of neon tubes of three colors, red, blue, and green. Such a neon unit 24 causes the corresponding neon tube to emit light based on the control signal output from the lighting control unit 22.

  The switching operation unit 25 is configured by a dip switch or the like, and is connected to the lighting control unit 22. The switching operation unit 25 can perform a mode switching operation for selectively switching the mode of the lighting control unit 22 to the normal mode or the data rewriting mode. For this reason, when the operation is performed by the switching operation unit 25, the operation signal is input to the lighting control unit 22.

  The setting operation unit 26 includes a dip switch or the like, and is connected to the lighting control unit 22. The setting operation unit 26 can be operated to set the number of updates between fixed pattern data recorded in the memory 22M of the lighting control unit 22.

  The lighting control unit 22 is a CPU unit including a CPU, ROM, RAM, and the like (not shown). Based on various signals input from the switching operation unit 25 and the setting operation unit 26, the lighting control and data rewrite control of the neon unit 24 are performed. I do.

  The lighting control unit 22 includes a nonvolatile memory 22M as recording means. In the present embodiment, the memory 22M stores a plurality of fixed pattern data indicating a time-series change mode of the lighting pattern of the neon unit 24 in association with the time-series number. Specifically, for example, as shown in FIG. 14A, each fixed pattern data includes start data and end data, and is set in correspondence with a time series number (here, “0” to “13”). ing. In the normal mode, the lighting control unit 22 controls the lighting of the neon unit 24 based on the start data and the end data of these fixed pattern data. When the switching operation unit 25 switches to the data rewriting mode, the lighting control unit 22 performs data rewriting control for updating the fixed pattern data based on the input signal from the external input device 6.

First, the lighting control of the neon unit 24 performed by the lighting control unit 22 will be described in detail.
(Lighting control of neon unit 24)
At the time of initial control, the lighting control unit 22 first reads the start data and end data of the fixed pattern data corresponding to the time series number “0” from the memory 22M.

  Then, the lighting control unit 22 uses the data change amount between the read start data and the end data and the number of updates set by the setting operation unit 26, and the intermediate data at each division point divided by the number of updates. Is calculated. Specifically, as shown in FIG. 4, first, the lighting control unit 22 performs a linear interpolation process between the start data and the end data, and calculates intermediate data between the two data. For example, when the number of updates is set to “10”, the lighting control unit 22 divides the data change amount between the two data calculated by the linear interpolation process into 10 parts, and “ A division point of “0” to “9” is given. Here, the lighting control unit 22 sets the start point (start data of fixed pattern data corresponding to the number data included in the update signal) as a division point “0”, and sets the end point (end data of the fixed pattern data) as the next point. It is set as a division point “0” in the number data. Therefore, pattern data (intermediate data) corresponding to each division point is obtained. FIG. 4 is a graph showing enlarged intermediate data while the number data changes from “0” to “1”. Also, “(number data)” shown in FIG. 4 is read as “(time series number)” in the present embodiment.

  First, the lighting control unit 22 performs lighting control of the neon unit 24 based on pattern data corresponding to the division point “0”, that is, start data. Incidentally, in this case, since the start data is “0”, the red neon tube of the neon unit 24 is turned off. Thereafter, the lighting control unit 22 performs the neon unit 24 based on the pattern data (intermediate data) corresponding to the division point “1” when a preset regular update time Δt (for example, “10 milliseconds”) has elapsed. Control the lighting of. Similarly, every time the regular update time Δt elapses, the lighting control unit 22 performs the neon unit based on the intermediate data corresponding to the division points “2” → “3” → “4” →. 24 lighting control is performed.

  After performing the lighting control of the neon unit 24 based on the intermediate data corresponding to the division point “9”, the lighting control unit 22 reads the fixed pattern data corresponding to the time series number “1” from the memory 22M, and performs the control. Similarly to the initial time, intermediate data data at each division point between the start data and the end data of the fixed pattern data is calculated. Then, the lighting control unit 22 performs lighting control of the neon unit 24 based on the intermediate data corresponding to the division point “9”, and then the division point “0” of the fixed pattern data corresponding to the time series number “1”. The neon unit 24 is turned on based on the pattern data (start data) corresponding to. For this reason, as shown in FIG. 4, the update time between each number data (update time between each fixed pattern data) T is a time obtained by multiplying the regular update time Δt by the number of updates (here, “(10 × 10)). Millisecond ", or" 100 milliseconds ").

(Operation of start data and end data)
Incidentally, as shown in FIG. 14A, for example, the value of the end data of the fixed pattern data corresponding to the time series number “0” is set to “30 (%)” and corresponds to the subsequent time series number “1”. The value of the start data of the fixed pattern data to be set is also set to “30 (%)”. That is, the end data value of the fixed pattern data at the time series number “0” and the start data value of the fixed pattern data corresponding to the next time series number “1” are set to be the same. . Therefore, as shown in FIGS. 4 and 14B, the value of the pattern data at the division point “0” of the time series number “1” is necessarily “30 (%)”.

  On the other hand, as shown in FIG. 14A, the value of the end data of the fixed pattern data corresponding to the time series number “7” is set to “100 (%)”, and the subsequent time series number “8”. The value of the start data of the corresponding fixed pattern data is set to “0 (%)”. For this reason, as shown in FIG. 6 and FIG. 14B, the value of the pattern data at the division point “0” of the time series number “8” is “100 (%)” and “0 (%)”. It becomes confused. However, in this case, the lighting control unit 22 updates the lighting pattern of the neon unit 24 based on the start data at the division point “0”. Therefore, at the division point “0” of the time series number “8”, the lighting pattern of the neon unit 24 is updated based on the start data of the corresponding fixed pattern data. Therefore, until the time point of the division point “9” of the time series number “7”, the red neon tube of the neon unit 24 is lit at the duty ratio of 100%, but the division point of the time series number “8”. At the time of “0”, the red neon tube is extinguished at once. Further, since the values of the start data and the end data of the fixed pattern data corresponding to the time series number “8” are both “0 (%)”, each of the division points “0” to “0” of the time series number “8”. The value of the intermediate data of “9” is also “0 (%)”. Then, the value of the pattern data becomes “100 (%)” again at the time of the division point “0” of the time series number “9”.

  Thus, if the value of the end data of the fixed pattern data corresponding to a certain time series number is different from the value of the start data of the fixed pattern data corresponding to the next time series number, the fixed pattern data is updated. When this is done, the lighting mode of the corresponding neon tube will change abruptly.

  On the other hand, when start data and end data are not set for each fixed pattern data, the time series number and the fixed pattern data have a relationship as shown in FIGS. 15A and 15B, for example. That is, in this case, since the intermediate data is set based on the linear interpolation process between the fixed pattern data, the time series number is updated from “7” to “8” as shown in FIG. Each intermediate data in between becomes a value that gradually decreases, and the pattern data becomes “0 (%)” when the time series number is updated to “8”. Then, each intermediate data becomes a value that gradually increases while the time series number is updated from “8” to “9”. When the time series number is updated to “9”, the pattern data is “100 (% ) ”. That is, the pattern data does not change sharply in this case as compared with the transition of the pattern data (see FIG. 14B) when the start data and the end data are set in the fixed pattern data. Therefore, as the number of updates increases, the pattern data tends to gradually change over time. In other words, if the start data and end data cannot be set in the fixed pattern data, the pattern data cannot be changed sharply in a short time, and the start data and end data can be set in the fixed pattern data. Therefore, the pattern data can be changed rapidly in a short time.

(Data rewrite control)
The lighting control unit 22 performs data rewriting control for updating the fixed pattern data based on an input signal from the external input device 6 when the switching operation unit 25 is switched to the data rewriting mode. Specifically, when switching from the normal mode to the data switching mode, the lighting control unit 22 records the fixed pattern data input from the external input device 6 in the memory 22M in association with the time series number. At this time, the lighting control unit 22 overwrites and updates the existing pattern data recorded in the memory 22M with new pattern data. Therefore, by operating the switching operation unit 25, the lighting control unit 22 is switched to the data rewriting mode, and new pattern data is input from the external input device 6 to the lighting control unit 22, so that the new data is stored in the memory 22M. Pattern data can be recorded.

(Relationship between update count and lighting pattern data over time)
Next, the relationship between the number of updates set by the setting operation unit 26 and the temporal transition of the lighting pattern will be described.

  For example, when the number of updates is set to “10” by the setting operation unit 26, the number data is updated every time the update time T elapses as shown in FIG. That is, in this case, the fixed pattern data is updated every time the update time T (= “100 milliseconds”) elapses. For this reason, when one lighting pattern is composed of number data “0” to “14”, the total time of the lighting pattern is (14 × T) seconds, that is, 1.4 seconds.

  On the other hand, for example, when the number of updates is set to “20” by the setting operation unit 26, the number data is updated every time the update time 2T (2 × T) elapses as shown in FIG. The Rukoto. That is, in this case, the fixed pattern data is updated every time when the time twice as long as the update count is set to “10” (“200 milliseconds”) elapses. Therefore, when the number data is “0” to “14” to form one lighting pattern, the total time of the lighting pattern is (14 × 2 × T) seconds, that is, 2.8 seconds. Therefore, the total time of the lighting pattern is twice that when the number of updates is set to “10”.

Therefore, according to the present embodiment, the following effects can be obtained.
(7) The pattern data includes the number of updates, the first number of times during the periodical update until the predetermined fixed pattern data (first fixed pattern data) is updated to the next fixed pattern data (second fixed pattern data). The data is updated to intermediate data obtained from the data change amount between the start data and the end data of the fixed pattern data. For this reason, the lighting mode of the neon unit 24 gradually changes based on the intermediate data until the fixed pattern itself is updated. On the other hand, if the end data value of the first fixed pattern data and the start data value of the second fixed pattern data are set to different values, the lighting pattern changes sharply when the fixed pattern data is updated. The lighting mode of the neon unit 24 changes abruptly. Therefore, the lighting mode of the neon unit 24 can be sharply changed by changing the end data of the predetermined fixed pattern data and the start data of the next fixed pattern data.

  (8) If the value of the update count set by the setting operation unit 26 increases, the update time T of the fixed pattern data becomes longer and the change rate of the lighting pattern becomes slower, and if the value of the update count decreases, the update of the fixed pattern data The time T is shortened and the change rate of the lighting pattern is increased. That is, by changing the number of updates, the update time T between the fixed pattern data can be changed, so that the change rate of the lighting pattern can be changed.

In addition, you may change embodiment of this invention as follows.
In the fourth embodiment, the setting operation unit 26 can collectively change the number of updates between all the fixed pattern data. However, the setting operation unit 26 may be able to individually set the number of updates between specific fixed pattern data. In this way, since the update time T between the fixed pattern data can be partially changed, the change rate of the lighting pattern of the neon unit 24 can be partially changed, and the fixed pattern data is changed. The neon unit 24 can be lit with a lighting pattern with completely different impressions.

  -In the said 4th Embodiment, the lighting control unit 4 does not necessarily need to be provided with the setting operation part 26, and the lighting control part 22 performs lighting control of the neon unit 24 based on the preset update frequency. It may be like this. That is, the lighting control unit 4 does not necessarily have a structure in which the changing speed of the lighting pattern of the neon unit 24 can be varied.

  In the first and second embodiments, the fixed pattern data may not be composed of start data and end data. That is, as shown in FIG. 7, the fixed pattern data may be constituted by a single fixed pattern data corresponding to each number data. This makes it impossible to make a steep change in the lighting pattern, but can reduce the recording capacity of the memory 22M.

In this case, the intermediate data is calculated by linearly interpolating the amount of change between the predetermined fixed pattern data and the fixed pattern data set in the next order.
In the first to third embodiments, any number of lighting control units 4 connected to the overall control unit 2 may be used as long as the number is one or more.

In each of the above embodiments, the intermediate data is not necessarily calculated based on the linear interpolation process, and may be calculated based on another interpolation process.
In order to set the number of updates, the setting operation unit 14 provided in the overall control unit 2 is used in each of the first to third embodiments, and provided in the lighting control unit 4 in the fourth embodiment. The setting operation unit 26 is used. However, the means for setting the number of updates (update number setting means) is not limited to the setting operation units 14 and 26, and may be configured by the external input device 6. In this case, the update control unit 12 in the first to third embodiments and the lighting control unit 22 in the fourth embodiment are based on the update number setting signal input from the external input device 6. Set the number of updates.

  In each of the above embodiments, the neon unit 24 having a neon tube is used as the light emitter. However, for example, an LED or an incandescent bulb may be used as the light emitter, and the lighting control unit 4 that controls the lighting of the LED or the incandescent bulb may be used. In the first to third embodiments, the lighting control system 1 includes a lighting control unit 4 that controls lighting of the neon unit 24 and a lighting control unit 4 that controls lighting of LEDs, incandescent bulbs, and the like. It may be.

Next, the technical ideas grasped by the embodiment described above are listed below.
(1) In the lighting control system according to any one of claims 1 to 6, the overall control unit includes an update count setting unit capable of setting an update count between the fixed pattern data. According to the invention described in the technical idea (1), the update can be performed only by the overall control unit, so that an external input device for setting the number of updates is not necessary.

The block diagram which shows schematic structure of the lighting control system of 1st Embodiment of this invention. The schematic diagram which shows the number data and fixed pattern data which are recorded on the lighting control unit of the same embodiment. (A) is a table | surface which shows the relationship between the number data of the same embodiment, and fixed pattern data, (b) is a graph which shows transition of the pattern data based on this table | surface. The graph which expands and shows a part of FIG.3 (b). The sequence chart which shows the flow of control with the integrated control unit and lighting control unit of the embodiment. The graph which expands and shows a part of FIG.3 (b). (A), (b) is the table | surface and graph which show the comparative example with FIG. (A), (b) is a graph which compares and shows the relationship between the frequency | count of an update, and the time transition of lighting pattern data. The block diagram which shows schematic structure of the lighting control system of 2nd Embodiment. The sequence chart which shows the flow of control with the integrated control unit and lighting control unit of the embodiment. The block diagram which shows schematic structure of the lighting control system of 3rd Embodiment. The sequence chart which shows the flow of control with the integrated control unit and lighting control unit of the embodiment. The block diagram which shows schematic structure of the lighting control apparatus of 4th Embodiment. (A) is a table | surface which shows the relationship between the time series number of the embodiment, and fixed pattern data, (b) is a graph which shows transition of the pattern data based on this table | surface. (A), (b) is the table | surface and graph which show the comparative example with FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 1 ... Lighting control system, 2 ... General control unit, 4 (4a-4d) ... Lighting control unit, 6 ... External input apparatus, 12 ... Update control part as speed control means, 12M, 22M ... Memory as recording means, Reference numerals 14 and 26 are setting operation sections as update count setting means, 22 are lighting control sections as lighting control means, and 24 are neon units as light emitters.

Claims (8)

Recording means for recording a plurality of fixed pattern data indicating time-sequential changes in the lighting pattern of the light emitter, and the lighting pattern of the light emitter by sequentially updating the fixed pattern data based on an input update signal A lighting control unit having a lighting control unit for controlling the lighting control unit, and a lighting control system including a general control unit that is connected to the lighting control unit through a network and sequentially outputs the update signals to the lighting control unit via the network. Because
The overall control unit includes speed control means for including update number data indicating the number of updates set to be changeable between the fixed pattern data in the update signal and outputting the update signal to the lighting control unit,
The lighting control means obtains the intermediate data at each point divided by the number of times of updating by performing interpolation processing between each fixed pattern data, and each time the preset regular update time elapses, A lighting control system, wherein the update time between each fixed pattern data is changed by sequentially updating the corresponding intermediate data. Each of the fixed pattern data is composed of a pair of pattern data each consisting of start data and end data,
The lighting control means turns on the light emitter with a lighting pattern based on the start data immediately after the update of the fixed pattern data, and updates every regular update time until the next fixed pattern data is updated. 2. The lighting according to claim 1, wherein the light-emitting body is turned on with a lighting pattern based on intermediate data obtained from the number of updates and a data change amount between the start data and the end data. Control system. A lighting control unit that controls a lighting pattern of a light emitter based on an input update signal, and a general control unit that is connected to the lighting control unit via a network and sequentially outputs the update signal to each lighting control unit via the network A lighting control system comprising:
The overall control unit includes a recording means for recording a plurality of fixed pattern data indicating a time-series change mode of the lighting pattern, an update count set to be changeable between the fixed pattern data, and a preset periodicity. Each fixed pattern data is sequentially output as the update signal for each calculation time obtained by multiplying by the update time, while intermediate data at each point divided by the number of updates is interpolated between the fixed pattern data. And an update control means for sequentially outputting the intermediate data corresponding to each point as the update signal for each regular update time each time the regular update time elapses. system. Each of the fixed pattern data is composed of a pair of pattern data each consisting of start data and end data,
The update control means outputs start data when outputting the fixed pattern data as the update signal, and outputs start data and end of the corresponding fixed pattern data when outputting the intermediate data as the update signal. 4. The lighting control system according to claim 3, wherein the intermediate data obtained by interpolating data is output. A lighting control unit that controls a lighting pattern of a corresponding light emitter based on an input update signal, and a network connection with the lighting control unit that sequentially outputs the update signal to each lighting control unit via the network A lighting control system comprising a control unit,
The overall control unit includes recording means for recording a plurality of fixed pattern data each including start data and end data, and indicating a time-series change mode of the lighting pattern, the fixed pattern data, and each fixed pattern data Speed control means for including update number data indicating the number of updates set to be changeable in the update signal and outputting it to the lighting control unit,
The lighting control unit divides between the input start data and end data of the fixed pattern according to the number of updates, and intermediate data at each divided point is between the start data and the end data. Is obtained by performing interpolation processing, and a lighting speed that changes the update time between each fixed pattern data by sequentially updating to the intermediate data corresponding to each point every time a preset periodic update time elapses A lighting control system comprising a changing means.   The lighting control system according to claim 1, wherein the number of updates between the fixed pattern data can be individually set. The illuminant is lit in a lighting mode based on a plurality of fixed pattern data indicating a time-series change mode of the lighting pattern of the illuminant and intermediate data obtained by interpolating between the fixed pattern data, and these are fixed. A lighting control device comprising a lighting control means for controlling a lighting pattern of the light emitter by sequentially updating pattern data and intermediate data every preset periodic update time,
The fixed pattern data is composed of start data and end data, respectively.
The lighting control means turns on the light emitter in a lighting mode based on the start data immediately after the update, and the start data is updated at the regular update time until the next fixed pattern data is updated. The lighting control device is characterized in that the light emitter is turned on with a lighting pattern based on intermediate data obtained from a data change amount between the data and the end data.   The lighting control device according to claim 7, further comprising an update count setting unit capable of changing an update count performed at each regular update time between the fixed pattern data.

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